Abstract
Physics-based predictive simulations of human movement have the potential to support personalized medicine, but large computational costs and difficulties to model control strategies have limited their use. We have developed a computationally efficient optimal control framework to predict human gaits based on optimization of a performance criterion without relying on experimental data. The framework generates three-dimensional muscle-driven simulations in 36 min on average—more than 20 times faster than existing simulations—by using direct collocation, implicit differential equations and algorithmic differentiation. Using this framework, we identified a multi-objective performance criterion combining energy and effort considerations that produces physiologically realistic walking gaits. The same criterion also predicted the walk-to-run transition and clinical gait deficiencies caused by muscle weakness and prosthesis use, suggesting that diverse healthy and pathological gaits can emerge from the same control strategy. The ability to predict the mechanics and energetics of a broad range of gaits with complex three-dimensional musculoskeletal models will allow testing novel hypotheses about gait control and hasten the development of optimal treatments for neuro-musculoskeletal disorders.
Highlights
Scientists have long tried to decipher the principles underlying bipedal locomotion with the aim of improving human gait performance and treatment of neuro-musculoskeletal disorders
Predictive simulations based on conceptual models have contributed to our understanding of the mechanics [1,2] and energetics [3,4,5,6] of bipedal locomotion
We developed a computationally efficient framework for predictive simulations of three-dimensional human gaits that allowed us to explore a broad range of control strategies and conditions
Summary
Scientists have long tried to decipher the principles underlying bipedal locomotion with the aim of improving human gait performance and treatment of neuro-musculoskeletal disorders. A powerful approach to this problem is the use of physics-based predictive simulations that generate de novo movements based on a mathematical description of the neuro-musculoskeletal system without relying on experimental data. Such simulations can explore diverse hypotheses about mechanisms underlying locomotion that are difficult to study through experiments. Predictive simulations based on conceptual models have contributed to our understanding of the mechanics [1,2] and energetics [3,4,5,6] of bipedal locomotion Such models provide limited support for personalized clinical decision-making, since they do not sufficiently describe the musculoskeletal structures and motor control processes underlying gait that may be affected by treatment
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